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[
2005]
RNA interference (RNAi) is a recently discovered phenomenon in which doublestranded RNA (dsRNA) silences endogenous gene expression in a sequencespecific manner (Fire et al., 1998). Since its discovery, the use of RNAi has become widely employed in many organisms to specifically knock down gene function. RNAi shares a remarkable degree of similarity with silencing phenomena in other organisms (Cogoni et al., 1999a; Sharp, 1999). For instance, RNAi, posttranscriptional gene silencing in plants and cosuppression in fungi can all be activated by the presence of aberrant RNAs (Maine, 2000; Tijsterman et al., 2002a). Additionally, plant, worm, and fly cells or extracts undergoing RNA-mediated interference all contain small dsRNAs, around 25 nucleotides in length, identical to the sequences present in the silenced gene (Baulcombe, 1996; Hammond et al., 2000; Zamore et al., 2000; Catalanotto et al., 2000). The high degree of similarity between these RNA-mediated silencing phenomena supports the notion that they were derived from an ancient and conserved pathway used to regulate gene expression, presumably to eliminate defective RNAs and to defend against viral infections and transposons. (Zamore, 2002). Components of RNAi have also been implicated in developmental processes, suggesting that RNAi may play a broader role in regulating gene expression (Smardon et al., 2000; Knight et al., 2001; et al., Ketting et al., 2001). Although we have learned much about the general mechanisms underlying RNAi, a detailed understanding of how RNAi works remains to be elucidated. In this chapter we will discuss first the biology of RNAi, then the genes required for its function, and we will end with a discussion on recent findings that have implicated chromatin silencing in the mechanism of RNAi.
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[
2006]
RNA interference (RNAi) describes a conserved biological response to double-stranded RNA (dsRNA) resulting in the degradation of homologous messenger RNA. In the last few years, this process of sequence-specific, post-transcriptional gene silencing has become a key technique for rapidly assessing gene function in species ranging from plants to mammals. Fire et al. provided the first insight into the RNAi mechanism by identifying dsRNA as the trigger of RNAi in Caenorhabditis elegans in 1998 [1]. However, a similar gene-silencing phenomenon was reported in earlier studies in both plants and Neurospora [2,3]. The basic RNAi response starts with long dsRNA being processed into small interfering RNAs (siRNAs) by a ribonuclease (RNase) III enzyme, Dicer. Next, the siRNA is incorporated into the RNA-induced silencing complex (RISC). For target RNA recognition to occur, the siRNA duplex must be unwound, allowing binding of one siRNA strand to the target mRNA. This is followed by RISC cleavage of the homologous mRNA. Recent work has shown that the RNAi machinery is also involved in antiviral responses, transposon silencing, development and heterochromatin formation [4].
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[
Methods Mol Biol,
2011]
Quantitative proteomics aims to identify and quantify proteins in cells or organisms that have been obtained from different biological origin (e.g., "healthy vs. diseased"), that have received different treatments, or that have different genetic backgrounds. Protein expression levels can be quantified by labeling proteins with stable isotopes, followed by mass spectrometric analysis. Stable isotopes can be introduced in vitro by reacting proteins or peptides with isotope-coded reagents (e.g., iTRAQ, reductive methylation). A preferred way, however, is the metabolic incorporation of heavy isotopes into cells or organisms by providing the label, in the form of amino acids (such as in SILAC) or salts, in the growth media. The advantage of in vivo labeling is that it does not suffer from side reactions or incomplete labeling that might occur in chemical derivatization. In addition, metabolic labeling occurs at the earliest possible moment in the sample preparation process, thereby minimizing the error in quantitation. Labeling with the heavy stable isotope of nitrogen (i.e., (15)N) provides an efficient way for accurate protein quantitation. Where the application of SILAC is mostly restricted to cell culture, (15)N labeling can be used for micro-organisms as well as a number of higher (multicellular) organisms. The most prominent examples of the latter are Caenorhabditis elegans and Drosophila (fruit fly), two important model organisms for a range of regulatory processes underlying developmental biology. Here we describe in detail the labeling with (15)N atoms, with a particular focus on fruit flies and C. elegans. We also describe methods for the identification and quantitation of (15)N-labeled proteins by mass spectrometry and bioinformatic analysis.
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[
Adv Exp Med Biol,
2010]
Nematode neuropeptide systems comprise an exceptionally complex array of approximately 250 peptidic signaling molecules that operate within a structurally simple nervous system of approximately 300 neurons. A relatively complete picture of the neuropeptide complement is available for Caenorhabditis elegans, with 30 flp, 38 ins and 43 nlp genes having been documented; accumulating evidence indicates similar complexity in parasitic nematodes from clades I, III, IV and V. In contrast, the picture for parasitic platyhelminths is less clear, with the limited peptide sequence data available providing concrete evidence for only FMRFamide-like peptide (FLP) and neuropeptide F (NPF) signaling systems, each of which only comprises one or two peptides. With the completion of the Schmidtea meditteranea and Schistosoma mansoni genome projects and expressed sequence tag datasets for other flatworm parasites becoming available, the time is ripe for a detailed reanalysis ofneuropeptide signalingin flatworms. Although the actual neuropeptides provide limited obvious value as targets for chemotherapeutic-based control strategies, they do highlight the signaling systems present in these helminths and provide tools for the discovery of more amenable targets such as neuropeptide receptors or neuropeptide processing enzymes. Also, they offer opportunities to evaluate the potential of their associated signaling pathways as targets through RNA interference (RNAi)-based, target validation strategies. Currently, within both helminth phyla, theflp signaling systems appear to merit further investigation as they are intrinsically linked with motor function, a proven target for successful anti-parasitics; it is clear that some nematode NLPs also play a role in motor function and could have similar appeal. At this time, it is unclear if flatworm NPF and nematode INS peptides operate in pathways that have utility for parasite control. Clearly, RNAi-based validation could be a starting point for scoring potential target pathways within neuropeptide signaling for parasiticide discovery programs. Also, recent successes in the application of in planta-based RNAi control strategies for plant parasitic nematodes reveal a strategy whereby neuropeptide encoding genes could become targets for parasite control. The possibility of developing these approaches for the control of animal and human parasites is intriguing, but will require significant advances in the delivery of RNAi-triggers.
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[
Methods Mol Biol,
2014]
Stable isotope labeling by amino acids combined with mass spectrometry is a widely used methodology for measuring relative changes in protein and phosphorylation levels at a global level. We have applied this method to the model organism Caenorhabditis elegans in combination with RNAi-mediated gene knockdown by feeding the nematode on pre-labeled lysine auxotroph Escherichia coli. In this chapter, we describe in details the generation of the E. coli strain, incorporation of heavy isotope-labeled lysine in C. elegans, and the procedure for a comprehensive global phosphoproteomic experiment.
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[
WormBook,
2006]
Through genetic analyses, the function of genes is investigated by studying organisms where gene function is altered. In classical forward genetic screening, individuals are treated with mutagens to induce DNA lesions and mutants with a phenotype of interest are sought. After a mutant is found, the gene mutated is identified through standard molecular techniques. Detailed studies of the mutant phenotype coupled with molecular analyses of the gene allows elucidation of the gene's function. Forward genetics has been responsible for our understanding of many biological processes and is an excellent method for identifying genes that function in a particular process.In reverse genetics, the functional study of a gene starts with the gene sequence rather than a mutant phenotype. Using various techniques, a gene's function is altered and the effect on the development or behaviour of the organism is analysed. Reverse genetics is an important complement to forward genetics. For example, using reverse genetics, one can investigate the function of all genes in a gene family, something not easily done with forward genetics. Further, one can study the function of a gene found to be involved in a process of interest in another organism, but for which no forward genetic mutants have yet been identified. Finally, the vast majority of genes have not yet been mutated in most organisms and reverse genetics allows their study. The availability of complete genome sequences combined with reverse genetics can allow every gene to be studied.This chapter gives detailed protocols for the two main methods of perturbing gene function in C. elegans: RNA interference and the creation of deletion mutants. Either technique can be applied to the study of individual genes. With less than a day of actual work, RNAi creates a knockdown of gene function without altering the organism's DNA (see below). In contrast, with about a month of work, a deletion mutation permanently removes all gene function. Deciding which technique to use will depend on the nature of the experiment. The techniques can also be combined, where RNAi is used for rapid screening of loss of function phenotypes and then deletion mutants are made to study genes of particular interest. RNAi can also be carried out on a global scale, where knockdown of (nearly) every gene is tested for inducing a phenotype of interest. In this case, the reverse genetics technique of RNAi can be thought of as a forward genetic screening tool.
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[
WormBook,
2005]
Understanding the biology of C. elegans relies on identification and analysis of essential genes, genes required for growth to a fertile adult. Approaches for identifying essential genes include several types of classical forward genetic screens, genome-wide RNA interference screens and systematic targeted gene knockout. Based on most estimates made from screening results thus far, from 15-30% of C. elegans genes appear to be essential. Genetic redundancy masks some essential functions and pleiotropy of many essential genes poses a challenge for a full understanding of their functions. Temperature sensitive mutations are valuable tools for studies of essential genes, but our ability to analyze essential genes would benefit from development of new tools for conditional inactivation or activation of specific genes.
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[
WormBook,
2005]
Alternative splicing is a common mechanism for the generation of multiple isoforms of proteins. It can function to expand the proteome of an organism and can serve as a way to turn off gene expression post-transcriptionally. This review focuses on splicing and its regulation in C. elegans. The fully-sequenced C. elegans genome combined with its elegant genetics offers unique advantages for exploring alternative splicing regulation in metazoans. The topics covered in this review include constitutive splicing factors, identification of alternatively spliced genes, examples of alternative splicing in C. elegans, and alternative splicing regulation. Key genes whose regulated alternative splicing are reviewed include
let-2 ,
unc-32 ,
unc-52 ,
egl-15 and
xol-1 . Factors involved in alternative splicing that are discussed include
mec-8 ,
smu-1 ,
smu-2 ,
fox-1 ,
exc-7 and
unc-75 .
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[
WormBook,
2006]
Receptor Tyrosine Kinase (RTK)/Ras GTPase/MAP kinase (MAPK) signaling pathways are used repeatedly during metazoan development to control many different biological processes. In the nematode Caenorhabditis elegans , two different RTKs ( LET-23 /EGFR and EGL-15 /FGFR) are known to stimulate LET-60 /Ras and a MAPK cascade consisting of the kinases LIN-45 /Raf, MEK-2 /MEK and MPK-1 /ERK. This Ras/MAPK cascade is required for multiple developmental events, including induction of vulval, uterine, spicule, P12 and excretory duct cell fates, control of sex myoblast migration and axon guidance, and promotion of germline meiosis. Studies in C. elegans have provided much insight into the basic framework of this RTK/Ras/MAPK signaling pathway, its regulation, how it elicits cell-type specific responses, and how it interacts with other signaling pathways such as the Wnt and Notch pathways.
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[
WormBook,
2006]
The completion of the C. elegans genome sequence permits the comprehensive examination of the expression and function of genes. Annotation of virtually every encoded gene in the genome allows systematic analysis of those genes using high-throughput assays, such as microarrays and RNAi. This chapter will center on the use of microarrays to comprehensively identify genes with enriched expression in the germ line during development. This knowledge provides a database for further studies that focus on gene function during germline development or early embryogenesis. Additionally, a comprehensive overview of germline gene expression can uncover striking biases in how genes expressed in the germ line are distributed in the genome, leading to new discoveries of global regulatory mechanisms in the germ line.